# This file is a part of Julia. License is MIT: https://julialang.org/license

eltype(::Type{<:AbstractSet{T}}) where {T} = @isdefined(T) ? T : Any
sizehint!(s::AbstractSet, n) = s

function copy!(dst::AbstractSet, src::AbstractSet)
    dst === src && return dst
    union!(empty!(dst), src)
end

## set operations (union, intersection, symmetric difference)

"""
    union(s, itrs...)
    ∪(s, itrs...)

Construct an object containing all distinct elements from all of the arguments.

The first argument controls what kind of container is returned.
If this is an array, it maintains the order in which elements first appear.

Unicode `∪` can be typed by writing `\\cup` then pressing tab in the Julia REPL, and in many editors.
This is an infix operator, allowing `s ∪ itr`.

See also [`unique`](@ref), [`intersect`](@ref), [`isdisjoint`](@ref), [`vcat`](@ref), [`Iterators.flatten`](@ref).

# Examples
```jldoctest
julia> union([1, 2], [3])
3-element Vector{Int64}:
 1
 2
 3

julia> union([4 2 3 4 4], 1:3, 3.0)
4-element Vector{Float64}:
 4.0
 2.0
 3.0
 1.0

julia> (0, 0.0) ∪ (-0.0, NaN)
3-element Vector{Real}:
   0
  -0.0
 NaN

julia> union(Set([1, 2]), 2:3)
Set{Int64} with 3 elements:
  2
  3
  1
```
"""
function union end

union(s, sets...) = union!(emptymutable(s, promote_eltype(s, sets...)), s, sets...)
union(s::AbstractSet) = copy(s)

const ∪ = union

"""
    union!(s::Union{AbstractSet,AbstractVector}, itrs...)

Construct the [`union`](@ref) of passed in sets and overwrite `s` with the result.
Maintain order with arrays.

# Examples
```jldoctest
julia> a = Set([3, 4, 5]);

julia> union!(a, 1:2:7);

julia> a
Set{Int64} with 5 elements:
  5
  4
  7
  3
  1
```
"""
function union!(s::AbstractSet, sets...)
    for x in sets
        union!(s, x)
    end
    return s
end

max_values(::Type) = typemax(Int)
max_values(T::Union{map(X -> Type{X}, BitIntegerSmall_types)...}) = 1 << (8*sizeof(T))
# saturated addition to prevent overflow with typemax(Int)
function max_values(T::Union)
    a = max_values(T.a)::Int
    b = max_values(T.b)::Int
    return max(a, b, a + b)
end
max_values(::Type{Bool}) = 2
max_values(::Type{Nothing}) = 1

function union!(s::AbstractSet{T}, itr) where T
    haslength(itr) && sizehint!(s, length(s) + Int(length(itr))::Int)
    for x in itr
        push!(s, x)
        length(s) == max_values(T) && break
    end
    return s
end

"""
    intersect(s, itrs...)
    ∩(s, itrs...)

Construct the set containing those elements which appear in all of the arguments.

The first argument controls what kind of container is returned.
If this is an array, it maintains the order in which elements first appear.

Unicode `∩` can be typed by writing `\\cap` then pressing tab in the Julia REPL, and in many editors.
This is an infix operator, allowing `s ∩ itr`.

See also [`setdiff`](@ref), [`isdisjoint`](@ref), [`issubset`](@ref Base.issubset), [`issetequal`](@ref).

!!! compat "Julia 1.8"
    As of Julia 1.8 intersect returns a result with the eltype of the
    type-promoted eltypes of the two inputs

# Examples
```jldoctest
julia> intersect([1, 2, 3], [3, 4, 5])
1-element Vector{Int64}:
 3

julia> intersect([1, 4, 4, 5, 6], [6, 4, 6, 7, 8])
2-element Vector{Int64}:
 4
 6

julia> intersect(1:16, 7:99)
7:16

julia> (0, 0.0) ∩ (-0.0, 0)
1-element Vector{Real}:
 0

julia> intersect(Set([1, 2]), BitSet([2, 3]), 1.0:10.0)
Set{Float64} with 1 element:
  2.0
```
"""
function intersect(s::AbstractSet, itr, itrs...)
    # heuristics to try to `intersect` with the shortest Set on the left
    if length(s)>50 && haslength(itr) && all(haslength, itrs)
        min_length, min_idx = findmin(length, itrs)
        if length(itr) > min_length
            new_itrs = setindex(itrs, itr, min_idx)
            return intersect(s, itrs[min_idx], new_itrs...)
        end
    end
    T = promote_eltype(s, itr, itrs...)
    if T == promote_eltype(s, itr)
        out = intersect(s, itr)
    else
        out = union!(emptymutable(s, T), s)
        intersect!(out, itr)
    end
    return intersect!(out, itrs...)
end
intersect(s) = union(s)
function intersect(s::AbstractSet, itr)
    if haslength(itr) && hasfastin(itr) && length(s) < length(itr)
        return mapfilter(in(itr), push!, s, emptymutable(s, promote_eltype(s, itr)))
    else
        return mapfilter(in(s), push!, itr, emptymutable(s, promote_eltype(s, itr)))
    end
end

const ∩ = intersect

"""
    intersect!(s::Union{AbstractSet,AbstractVector}, itrs...)

Intersect all passed in sets and overwrite `s` with the result.
Maintain order with arrays.
"""
function intersect!(s::AbstractSet, itrs...)
    for x in itrs
        intersect!(s, x)
    end
    return s
end
intersect!(s::AbstractSet, s2::AbstractSet) = filter!(in(s2), s)
intersect!(s::AbstractSet, itr) =
    intersect!(s, union!(emptymutable(s, eltype(itr)), itr))

"""
    setdiff(s, itrs...)

Construct the set of elements in `s` but not in any of the iterables in `itrs`.
Maintain order with arrays.

See also [`setdiff!`](@ref), [`union`](@ref) and [`intersect`](@ref).

# Examples
```jldoctest
julia> setdiff([1,2,3], [3,4,5])
2-element Vector{Int64}:
 1
 2
```
"""
setdiff(s::AbstractSet, itrs...) = setdiff!(copymutable(s), itrs...)
setdiff(s) = union(s)

"""
    setdiff!(s, itrs...)

Remove from set `s` (in-place) each element of each iterable from `itrs`.
Maintain order with arrays.

# Examples
```jldoctest
julia> a = Set([1, 3, 4, 5]);

julia> setdiff!(a, 1:2:6);

julia> a
Set{Int64} with 1 element:
  4
```
"""
function setdiff!(s::AbstractSet, itrs...)
    for x in itrs
        setdiff!(s, x)
    end
    return s
end
function setdiff!(s::AbstractSet, itr)
    for x in itr
        delete!(s, x)
    end
    return s
end


"""
    symdiff(s, itrs...)

Construct the symmetric difference of elements in the passed in sets.
When `s` is not an `AbstractSet`, the order is maintained.

See also [`symdiff!`](@ref), [`setdiff`](@ref), [`union`](@ref) and [`intersect`](@ref).

# Examples
```jldoctest
julia> symdiff([1,2,3], [3,4,5], [4,5,6])
3-element Vector{Int64}:
 1
 2
 6

julia> symdiff([1,2,1], [2, 1, 2])
Int64[]
```
"""
symdiff(s, sets...) = symdiff!(emptymutable(s, promote_eltype(s, sets...)), s, sets...)
symdiff(s) = symdiff!(copy(s))

"""
    symdiff!(s::Union{AbstractSet,AbstractVector}, itrs...)

Construct the symmetric difference of the passed in sets, and overwrite `s` with the result.
When `s` is an array, the order is maintained.
Note that in this case the multiplicity of elements matters.
"""
function symdiff!(s::AbstractSet, itrs...)
    for x in itrs
        symdiff!(s, x)
    end
    return s
end

symdiff!(s::AbstractSet, itr) = symdiff!(s::AbstractSet, Set(itr))

function symdiff!(s::AbstractSet, itr::AbstractSet)
    for x in itr
        x in s ? delete!(s, x) : push!(s, x)
    end
    return s
end

## non-strict subset comparison

const ⊆ = issubset
function ⊇ end
"""
    issubset(a, b) -> Bool
    ⊆(a, b) -> Bool
    ⊇(b, a) -> Bool

Determine whether every element of `a` is also in `b`, using [`in`](@ref).

See also [`⊊`](@ref), [`⊈`](@ref), [`∩`](@ref intersect), [`∪`](@ref union), [`contains`](@ref).

# Examples
```jldoctest
julia> issubset([1, 2], [1, 2, 3])
true

julia> [1, 2, 3] ⊆ [1, 2]
false

julia> [1, 2, 3] ⊇ [1, 2]
true
```
"""
issubset, ⊆, ⊇

const FASTIN_SET_THRESHOLD = 70

function issubset(a, b)
    if haslength(b) && (isa(a, AbstractSet) || !hasfastin(b))
        blen = length(b) # conditions above make this length computed only when needed
        # check a for too many unique elements
        if isa(a, AbstractSet) && length(a) > blen
            return false
        end
        # when `in` would be too slow and b is big enough, convert it to a Set
        # this threshold was empirically determined (cf. #26198)
        if !hasfastin(b) && blen > FASTIN_SET_THRESHOLD
            return issubset(a, Set(b))
        end
    end
    for elt in a
        elt in b || return false
    end
    return true
end

"""
    Base.hasfastin(T)

Determine whether the computation `x ∈ collection` where `collection::T` can be considered
as a "fast" operation (typically constant or logarithmic complexity).
The definition `hasfastin(x) = hasfastin(typeof(x))` is provided for convenience so that instances
can be passed instead of types.
However the form that accepts a type argument should be defined for new types.

The default for `hasfastin(T)` is `true` for subtypes of
[`AbstractSet`](@ref), [`AbstractDict`](@ref) and [`AbstractRange`](@ref)
and `false` otherwise.
"""
hasfastin(::Type) = false
hasfastin(::Union{Type{<:AbstractSet},Type{<:AbstractDict},Type{<:AbstractRange}}) = true
hasfastin(x) = hasfastin(typeof(x))

⊇(a, b) = b ⊆ a

## strict subset comparison

function ⊊ end
function ⊋ end
"""
    ⊊(a, b) -> Bool
    ⊋(b, a) -> Bool

Determines if `a` is a subset of, but not equal to, `b`.

See also [`issubset`](@ref) (`⊆`), [`⊈`](@ref).

# Examples
```jldoctest
julia> (1, 2) ⊊ (1, 2, 3)
true

julia> (1, 2) ⊊ (1, 2)
false
```
"""
⊊, ⊋

⊊(a::AbstractSet, b::AbstractSet) = length(a) < length(b) && a ⊆ b
⊊(a::AbstractSet, b) = a ⊊ Set(b)
⊊(a, b::AbstractSet) = Set(a) ⊊ b
⊊(a, b) = Set(a) ⊊ Set(b)
⊋(a, b) = b ⊊ a

function ⊈ end
function ⊉ end
"""
    ⊈(a, b) -> Bool
    ⊉(b, a) -> Bool

Negation of `⊆` and `⊇`, i.e. checks that `a` is not a subset of `b`.

See also [`issubset`](@ref) (`⊆`), [`⊊`](@ref).

# Examples
```jldoctest
julia> (1, 2) ⊈ (2, 3)
true

julia> (1, 2) ⊈ (1, 2, 3)
false
```
"""
⊈, ⊉

⊈(a, b) = !⊆(a, b)
⊉(a, b) = b ⊈ a

## set equality comparison

"""
    issetequal(a, b) -> Bool

Determine whether `a` and `b` have the same elements. Equivalent
to `a ⊆ b && b ⊆ a` but more efficient when possible.

See also: [`isdisjoint`](@ref), [`union`](@ref).

# Examples
```jldoctest
julia> issetequal([1, 2], [1, 2, 3])
false

julia> issetequal([1, 2], [2, 1])
true
```
"""
issetequal(a::AbstractSet, b::AbstractSet) = a == b
issetequal(a::AbstractSet, b) = issetequal(a, Set(b))

function issetequal(a, b::AbstractSet)
    if haslength(a)
        # check b for too many unique elements
        length(a) < length(b) && return false
    end
    return issetequal(Set(a), b)
end

function issetequal(a, b)
    haslength(a) && return issetequal(a, Set(b))
    haslength(b) && return issetequal(b, Set(a))
    return issetequal(Set(a), Set(b))
end

## set disjoint comparison
"""
    isdisjoint(a, b) -> Bool

Determine whether the collections `a` and `b` are disjoint.
Equivalent to `isempty(a ∩ b)` but more efficient when possible.

See also: [`intersect`](@ref), [`isempty`](@ref), [`issetequal`](@ref).

!!! compat "Julia 1.5"
    This function requires at least Julia 1.5.

# Examples
```jldoctest
julia> isdisjoint([1, 2], [2, 3, 4])
false

julia> isdisjoint([3, 1], [2, 4])
true
```
"""
function isdisjoint(a, b)
    function _isdisjoint(a, b)
        hasfastin(b) && return !any(in(b), a)
        hasfastin(a) && return !any(in(a), b)
        haslength(b) && length(b) < FASTIN_SET_THRESHOLD &&
            return !any(in(b), a)
        return !any(in(Set(b)), a)
    end
    if haslength(a) && haslength(b) && length(b) < length(a)
        return _isdisjoint(b, a)
    end
    _isdisjoint(a, b)
end

function isdisjoint(a::AbstractRange{T}, b::AbstractRange{T}) where T
    (isempty(a) || isempty(b)) && return true
    fa, la = extrema(a)
    fb, lb = extrema(b)
    if (la < fb) | (lb < fa)
        return true
    else
        return _overlapping_range_isdisjoint(a, b)
    end
end

_overlapping_range_isdisjoint(a::AbstractRange{T}, b::AbstractRange{T}) where T = invoke(isdisjoint, Tuple{Any,Any}, a, b)

function _overlapping_range_isdisjoint(a::AbstractRange{T}, b::AbstractRange{T}) where T<:Integer
    if abs(step(a)) == abs(step(b))
        return mod(minimum(a), step(a)) != mod(minimum(b), step(a))
    else
        return invoke(isdisjoint, Tuple{Any,Any}, a, b)
    end
end

## partial ordering of sets by containment

==(a::AbstractSet, b::AbstractSet) = length(a) == length(b) && a ⊆ b
# convenience functions for AbstractSet
# (if needed, only their synonyms ⊊ and ⊆ must be specialized)
<( a::AbstractSet, b::AbstractSet) = a ⊊ b
<=(a::AbstractSet, b::AbstractSet) = a ⊆ b

## filtering sets

filter(pred, s::AbstractSet) = mapfilter(pred, push!, s, emptymutable(s))

# it must be safe to delete the current element while iterating over s:
unsafe_filter!(pred, s::AbstractSet) = mapfilter(!pred, delete!, s, s)

# TODO: delete mapfilter in favor of comprehensions/foldl/filter when competitive
function mapfilter(pred, f, itr, res)
    for x in itr
        pred(x) && f(res, x)
    end
    res
end
